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Chapter 5
Thermochemistry
5.1 Energy and Energy Changes:
•Energy is involved in all types of physical and chemical changes
•Energy: the capacity to do work or transfer heat
•All forms of energy are either:
-Kinetic:energyofmotion
-Potential:energy of position
-Kinetic energy:
Where m is mass and u is velocity
(Thermal energy is form of kinetic energy
associated with random motion)
Monitorchangesviachanges in temperature
•Potential energy:
–Chemical energy is stored within structural units of chemical substances.
Electrostatic energy:
Dependent on charges and distance between charges
(Q = charge and d = distance)
+ Eel: repulsiveand− Eel: attractive
•Law of conservation of energy:
–Energy may be converted from one form to another.
–The total amount of energy in the universe is constant.
Example:
•A chemical reaction (potential) gives off heat (thermal)
•Energy changes in chemical reactions:
–System is the part of the universe of interest.
Example:
The reactants NaOH and HCl
–Surroundings are the rest of the universe.
Example:
When heat is given off from the reaction of NaOH and HCl, the energy is transferred from the system to the surroundings.
•Thermochemistry:
–The study of the transfer of heat (thermal energy) in chemical reactions.
–Exothermic- transfer of heat from the system to the surroundings
2H2(g) + O2(g) 2H2O(l) + energy
–Endothermic- the transfer of heat from the surroundings to the system
energy + 2HgO(s) 2Hg(l) + O2(g)
Comparison of Endothermic and Exothermic Processes
•Units of Energy:
–Joule(J) is the SI unit for energy.
The amount of energy possessed by a 2 kg mass moving at a speed of 1 m/s
–Calorie(cal)- commonly used on food labels
–1 cal 4.184 J
–1000 cal = 1 Cal = 1 kcal
–Food calories (Cal) are really 1000 calories (cal).
Calculate the kinetic energy of a neon atom moving at a speed of 98 m/s.
5.2 Introduction to Thermodynamics
•Types of systems:
–open (exchange of mass and energy)
–closed (exchange of energy)
–isolated (no exchange)
Open Closed
Isolated
State functions:
depend only on initialand final states of the system and not on how the change was carried out.
Energy (E)
Pressure (P)
Volume (V)
Temperature (T)
First Law of Thermodynamics
“Energy can be converted from one form to another
but cannot be created or destroyed”.
Based on the law of conservation of energy:
Internal energy (U):
–Kinetic energy - molecular motion
–Potential energy - attractive/repulsive
Interactions
• The change in internal energy of a system
between final (f) and initial (i) states is
defined as:
U = Uf Ui
•For a chemical system:
–Can calculate the change in energy of the system experimentally:
U = U(products)U(reactants)
Consider:
S(s) + O2(g) SO2(g)
This reaction releases heat, therefore U is negative.
When a system releases heat, some of the chemical energy is released as thermal energy to the surroundings but this does not change the total energy of the universe.
Usystem + Usurroundings = 0
When a system undergoes a change in
energy, the surroundings must undergo a
change in energy equal in magnitude and
opposite in sign.
Usystem = Usurroundings
•Work and heat :
Usys = q + w
whereq is heat and w is work
Workis defined as force to a distance:
work = force x distance
W =F x h
But: pressure = force/Area
P = F/A
or F = P x A
W =P x A x h
whenpressure is applied by system to surroundings: W = -PV
Usys = q- PV
(Note: 1atm L = 101J)
When work is done by the system the result is an expansionof the system and the work is negative (ΔV is positive)
When work is done on the system, the result is compression of the system and the work is positive (ΔV is negative)
Calculate the overall change in internal energy for a system that absorbs 125 J of heat and does 141 J of work on the surroundings.
q is + (heat absorbed)
w is (work done)
Usys = q + w = (+125 J) + (141J) = 16 J
5.3.Reactions carried out at constant at Volume and Pressure:
•Reactions carried out at constant volume:
–Pressure-volume work, w, done by a system is:
w = PV
–Constant volume:
V = 0
U = qPV
qv= U(at constant volume)
•Reactions carried out at constant pressure:
U = q + w
U = qpPV
qp= U + PV
•Enthalpy and enthalpy changes:
–Enthalpy (H) is a state function defined as
H = U + PV
–At constant pressure:
qp =H(at constant pressure)
–Enthalpy of reaction:
•H is + for endothermic changes.
•H is − for exothermic changes.
•Thermochemical Equations:
–Equations that represent both mass and enthalpy changes:
H2O(s) H2O(l) H = + 6.01 kJ/mol
•This is an endothermic process. It requires 6.01 kJ to melt one mole of ice, H2O(s).
•The enthalpy value will change if the number of moles varies from the 1:1 reaction stoichiometry.
•This is an exothermic process. It releases
890.4 kJ when one mole of methane, CH4,reacts.
•The enthalpy value will change if the number of moles varies from the 1:2:1:2 reaction stoichiometry.
Comparison of Endothermic and Exothermic Changes
Given the following equation:
C6H12O6(s) + 6O2(g) → 6CO2(g) + 6H2O(l)
ΔH = 2803 kJ/mol
Calculate the energy released when 45.00 g of glucose(MM = 180.2 g/mol) is burned in oxygen:
5.4 Calorimetry:
•Calorimetryis the measurement of heat changes
•Heat capacity (C):
It is the amount of heat required to raise the temp of
an object by 1°C.
–Units: J/°C
–Relation to amount of heat (q)
where q is heat, m is mass, C is heat capacityand
T = change in temp (T = TfinalTinitial)
Calculate the amount of energy required to heat 95.0 grams of water from 22.5°C to 95.5°C.
T = Tfinal – Tinitial = 95.5 oC − 22.5oC = 73.0oC and
q = (95.0 g) (4.184 J/g°C) (73.0°C) = 2.90 x 104 J or 29.0 kJ
•Specific heat (s):the amount of heat required to raise the
the temp of 1 g of a substance by 1°C.
–Units: J/g °C
–Relation to amount of heat (q):
where q is heat, m is mass, s is specific heat
andT = change in temp (T = TfinalTinitial)
•Constant-Pressure Calorimetry:
=H(for good approximation)
–System: reactants and products
–Surroundings: water
Used to measure: Specific heatsand H values
A metal pellet with a mass of 85.00 grams at an original temperature of 92.5°C (Ti,metal) is dropped into a calorimeter with 150.00 grams of water at an original temperature of 23.1°C (Ti, water). The final temperature of the water and the pellet is 26.8°C (Tf). Calculate the heat capacity and the specific heat for the metal
qwater = msT
= (150.00 g) (4.184 J/g°C) (3.7°C)
= 2300 J (water gained energy)
qpellet=-qwater = -2300 J (pellet released energy)
Heat capacityof pellet:
q = CT
and C = q/T
= (2300 J)/(65.7°C) = 35 J/°C
butSpecific heatof pellet is in J/goC:
•Constant-Volume Calorimetry:
For isolated system:
–Measures U using bomb calorimeter:
A snack chip with a mass of 2.36 g was burned in a bomb calorimeter. The heat capacity of the calorimeter 38.57 kJ/°C. During the combustion the water temp rose by 2.70°C. Calculate the energy in kJ/g for the chip.
qrxn= −CcalT
= −(38.57 kJ/°C) (2.70°C)
= − 104 kJ
Energy content is a positive quantity:
E = qv
Energy content = 104 kJ/2.36 g
= 44.1 kJ/g (positive quantity)
(Food Calories: 10.5 Cal/g)
5.5Hess’s Law:
The change in enthalpy that occurs when reactants are converted to products is the same whether the reaction occurs in one step or a series of steps.
Therefore chemical reactions and their enthalpy
changes can be treated as mathematical equations:
If a reaction is reversed, the sign of ΔH is also reversed.
e. g:A + BZ ΔH = +231kJ
A + BZ ΔH = -231kJ
If the coefficients in a balance equation are multiplied by an integer, the value of ΔH is multiplied by the same integer.
e. g:A + 1/2B 2ZΔH = +231kJ
2A + B 4ZΔH = +462kJ
Used for calculating enthalpy for a reaction that
cannot be determined directly.
Calculate ΔH for the conversion of graphite to
diamond:
Cgraphite (s) Cdiamond (s)ΔH= ?
Making use of their combustion enthalpies:
Cgraphite(s) + O2(g) CO2(g)ΔH1 = - 394 kJ
Cdiamond(s) + O2(g) CO2(g)ΔH2 = - 396 kJ
By revesing reaction (2) and add to reaction (1) gives the required reaction:
Cgraphite(s) + O2(g) CO2(g)ΔH1 = -394 kJ
CO2(g) Cdiamond(s) + O2(g)ΔH3 = +396 kJ
______
Cgraphite(s) Cdiamond(s)ΔH = ΔH1 + ΔH3 = +2 kJ
Since ΔH is positive the reaction is endothermic.
Given the following equations:
H3BO3(aq) HBO2(aq) + H2O(l) Hrxn = 0.02 kJ
H2B4O7(aq) + H2O(l) 4 HBO2(aq) Hrxn= 11.3 kJ
H2B4O7(aq) 2 B2O3(s) + H2O(l) Hrxn = 17.5 kJ
Find the H for this overall reaction.
2H3BO3(aq) B2O3(s) + 3H2O(l) Hrxn = ?
2H3BO3(aq) 2HBO2(aq) + 2H2O(l) x 2
Hrxn = 2(−0.02 kJ) = −0.04 kJ
2HBO2(aq)1/2H2B4O7(aq) + 1/2H2O(l) reverse, ÷2
Hrxn= +11.3 kJ/2 = 5.65 kJ
1/2H2B4O7(aq) B2O3(s)+ 1/2H2O(l) ÷2
Hrxn = 17.5 kJ/2 = 8.75 kJ
2H3BO3(aq) B2O3(s) + 3H2O(l)
Hrxn = 14.36 kJ
5.6Standard Enthalpies of Formation:
Standard enthalpy of formation
–Symbol: Hf°
–The enthalpy change that results when 1 mole of a compound is formed from its elements in their standard states.
-Hf° for an element in its standard state is defined as zero.
–Standard state: 1 atm, 25°C
–Values found in reference tables
–Used to calculate the H°rxn
•Defining equation for enthalpy of reaction:
ΔHoreaction = npΔHof(products) – nr ΔHof(reactants)
wherenp and nr are the coefficients of the products and
thereactants in the balance equation
Note: The enthalpy of formation of an element in its standard state is zero. (e.g: H2(g), O2(g), N2(g), Cgraphite(s), F2(g), Cl2(g), Br2(l), I2(s), metals(s) and Hg (l).
Calculate the H°rxnfor the following reactionfrom the table of standard values:
CH4(g) + 2O2(g) CO2(g) + 2H2O(l)
Hrxn° =npHf° (products) - nrHf°(reactants)
= [1(393.5) + 2(285.8)] [1(74.8) + 2(0)]
= 890.3 kJ/mol (exothermic)